Universal keyboard

ABSTRACT

A biometric analyzer, including a biometric generator, receiving user input in conformance with a layout of keys, and generating therefrom time series, over a period of time, of touch location, touch timing and touch pressure data, for transmission as a data stream to a biometric identifier, wherein the time series of touch timing data includes a series of times at which keys are depressed and times at which the depressed keys are released, and wherein the time series of touch pressure data includes a series of pressure magnitudes, and a biometric identifier, receiving the time series from the biometric generator, deriving a biometric template of the user therefrom, and subsequently when the user tries to access a system using a keyboard, identifying the user based on his biometric template, and granting or restricting the user&#39;s access to the system, based on his biometric template.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent application Ser. No. 14/809,290 entitled UNIVERSAL KEYBOARD, and filed on Jul. 27, 2015 by inventors Jordan A. Berger and John V. Monaco.

FIELD OF THE INVENTION

The present invention relates to electronic keyboards.

BACKGROUND OF THE INVENTION

The keyboard is one of the most universal peripheral components for desktop and laptop computers, and yet it relies on the QWERTY system that dates back to the 1870's. It is arguably the most ancient part of the desktop and laptop computers in use today. The use of keyboards is ubiquitous with word processing, web browsing, multimedia streaming and gaming.

Many applications remap keys or key sequences to application-specific commands. For example, “Ctrl+n” creates a new document or opens a new window, depending on the context. The keyboard layout can be entirely remapped through software. The standard QWERTY layout is often associated with a US English key map, but many others exist. For example, some users switch to a DVORAK layout due to comfort, or use a language other than English on a QWERTY keyboard. Many applications allow the user to create time saving “macros”, but most users do not take advantage of them due to the high barrier of learning how to program the macros. Users often purchase more than one keyboard or controller, each one made for a specific purpose. For word processing, some users like to use a keyboard with a relatively light touch, but when gaming they prefer a mechanical keyboard with a heavier pressure. Many gaming applications only utilize about 8 keys, and the unused keys become obsolete during gameplay. Many users in the graphics and imaging fields execute thousands of mouse clicks per day to perform tasks that could be highly simplified with a more intelligent human-computer interface.

The current field of keystroke dynamics, as described in

-   M. Karnan, M. Akila, N. Krishnaraj, Biometric personal     authentication using keystroke dynamics: A review, Applied Soft     Computing, Vol. 11, Issue 2, March 2011, pages 1565-1573, ISSN     1568-4946, http://dx.doi.org/10.1016/j.asoc.2010.08.003,     http://www.sciencedirect.com/science/article/pil/S156849461000205X,     and -   Pin Shen Teh, Andrew Beng Jin Teoh, and Shigang Yue, “A Survey of     Keystroke Dynamics Biometrics,” The Scientific World Journal, Vol.     2013, Article ID 408280, 24 pages, 2013. doi:10.1155/2013/408280,     utilizes behavioral biometric data from users, as described in -   Fabian Monrose, Aviel D. Rubin, Keystroke dynamics as a biometric     for authentication, Future Generation Computer Systems, Vol. 16,     Issue 4, February 2000, pages 351-359, ISSN 0167-739X,     http://dx.doi.org/10.1016/S0167-739X(99)00059-X,     http://www.sciencedirect.com/science/article/pil/S0167739X9900059X,     in order to perform a variety of important functions, such as     on-line user authentication, as described in -   Bergadano, Francesco, Gunetti, Daniele, and Claudia Picardi, User     authentication through keystroke dynamics, ACM Transactions on     Information and System Security (TISSEC), Vol. 5, issue 4, November     2002, pages 367-397, New York, ACM, ISSN: 1094-9224 EISSN: 1557-7406     doi:10.1145/581271.581272.     Researchers are studying use of keystrokes to detect physical     ailments such as arthritis and Parkinson's disease,     http://www.nature.com/srep/2015/150409/srep09678/full/srep09678.html).

Keyboards commercially available today are limited in that they can only provide timing information, while it has been shown that use of additional sensors, such as pressure and acceleration, significantly improves the performance of a keystroke biometric system. The demand for additional sensors continues to grow as keystroke dynamics is incorporated into an increasing number of applications.

Prior art virtual keyboards project onto surfaces, and will never likely be a “preferred” keyboard for any user. Virtual keyboards have a futuristic appearance, and can be used in place of keyboards for short sessions, but for the “normal” or “heavy” computer user, the virtual keyboard lacks many features.

Conventional and virtual keyboards can output keystrokes (“all or none”) and timing data, but cannot measure pressure data, and lack the spatial resolution that allows, for example, estimation of finger size, limiting their use in advanced behavioral biometrics.

SUMMARY OF THE DESCRIPTION

Embodiments of the present invention relate to a universal keyboard, which is dynamically optimized for all key input to the computer, and is the first fully-compatible biometric keyboard. The keyboard includes a blank translucent surface, a capacitive array touch screen that transmits touch to the computer, and a projection system that dynamically projects the keyboard template or layout that is needed for each application. There are inter alia four types of projection systems: (1) micro-LED array applied to the under-surface of the keyboard, (2) projection system applied to a bar across the keyboard, (3) projection system that projects onto the surface from underneath the keyboard, and (4) touchscreen system.

The universal keyboard includes inter alia a speaker, a microphone, a webcam, an accelerometer, a USB connection, and an optional wireless module such as a BLUETOOTH® module.

The universal keyboard includes a device driver that initializes the keyboard, the projection system, the microphone, the webcam and a touch pad, that initializes a BLUETOOTH® pairing, that loads a sound file, and that dynamically projects a display file onto the keyboard. The driver also maps touch data to ASCII keystroke or bitmap data, as appropriate, formats the keystroke or bitmap data for output, and outputs the data via USB or such other data channel. Data output from the keyboard via the device driver may use a file format and communications protocol that conform to an existing or future standard.

There is thus provided in accordance with an embodiment of the present invention a biometric analyzer, including a biometric generator, receiving user input in conformance with a layout of keys, and generating therefrom time series, over a period of time, of touch location data, of touch timing data and of touch pressure data, for transmission as a data stream to a biometric identifier, wherein the time series of touch location data includes a series of locations of keys that are pressed by the user, wherein the time series of touch timing data includes a series of times at which keys are depressed and times at which the depressed keys are released, and wherein the time series of touch pressure data includes a series of pressure magnitudes, and a biometric identifier, receiving the time series of touch location, touch timing and touch pressure data from the biometric generator, deriving a biometric template of the user therefrom, and subsequently when the user tries to access a system using a keyboard, identifying the user based on his biometric template, and granting or restricting the user's access to the system, based on his biometric template.

There is additionally provided in accordance with an embodiment of the present invention a method for biometric analysis, including receiving user input in conformance with a layout of keys, generating, from the user input, time series, over a period of time, of touch location data, touch timing data and touch pressure data, wherein the time series of touch location data includes a series of locations of keys that are pressed by the user, wherein the time series of touch timing data includes a series of times at which keys are depressed and times at which the depressed keys are released, and wherein the time series of touch pressure data includes a series of pressure magnitudes, deriving a biometric template of the user from the times series of touch location, touch timing and touch pressure data, and subsequently, when the user tries to access a system: identifying the user based on his biometric template, and granting or restricting the user's access to the system, based on the user's biometric template.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be more fully understood and appreciated from the following detailed description, taken in conjunction with the drawings in which:

FIG. 1 is a simplified diagram of a keyboard for use in cooperation with a keystroke biometric analyzer, in accordance with an embodiment of the present invention;

FIG. 2 is a simplified diagram of a keyboard with interactive generation of layouts of keys, in accordance with an embodiment of the present invention;

FIG. 3 is a simplified top view of a keyboard, in accordance with an embodiment of the present invention;

FIG. 4 is a simplified side view of the keyboard of FIG. 3 showing four layers, in accordance with an embodiment of the present invention;

FIG. 5 is a simplified illustration of a layout of keys for word processing, for use with the keyboard of FIG. 3, in accordance with an embodiment of the present invention;

FIG. 6 is a simplified illustration of a layout of keys for an alternate language, for use with the keyboard of FIG. 3, in accordance with an embodiment of the present invention.

FIG. 7 is a simplified illustration of a layout of keys for an interactive MINECRAFT® game, for use with the keyboard of FIG. 3, in accordance with an embodiment of the present invention.

FIG. 8 is a simplified flowchart of a method for using a keyboard to generate data for a keystroke biometric analyzer, in accordance with an embodiment of the present invention;

FIG. 9 is a simplified flowchart of a method for interactively generating layouts of keys for a keyboard, in accordance with an embodiment of the present invention;

FIG. 10 is a simplified diagram of a keyboard device driver, in accordance with an embodiment of the present invention;

FIG. 11 is a simplified diagram of a mouse device driver, in accordance with an embodiment of the present invention;

FIG. 12 is a simplified diagram of a keyboard using a micro-LED array projection system, in accordance with an embodiment of the present invention;

FIG. 13 is a simplified diagram of a keyboard using a projection system applied to a bar across the keyboard, in accordance with an embodiment of the present invention;

FIG. 14 is a simplified diagram of a keyboard using a projection system that projects onto the surface from underneath the keyboard, in accordance with an embodiment of the present invention;

FIG. 15 is a simplified diagram of a keyboard using a touchscreen, in accordance with an embodiment of the present invention; and

FIG. 16 is a simplified diagram of the biometric analyzer of FIG. 1, in accordance with an embodiment of the present invention; and

FIG. 17 is a simplified flowchart of biometric analysis and authentication, in accordance with an embodiment of the present invention.

For reference to the figures, the following index of elements and their numerals is provided. Similarly numbered elements represent elements of the same type, but they need not be identical elements.

Table of elements in the figures Element Description 100 keyboard 110 blank transparent surface 120 capacitive surface 140 projection system 150 controller 160 speaker 165 microphone 170 webcam 175 accelerometer 180 USB connector 185 wireless module 190 biometric generator 200 keyboard 210 blank transparent surface 220 capacitive surface 240 projection system 250 controller 260 speaker 265 microphone 270 webcam 275 accelerometer 280 USB connector 285 wireless module 290 dynamic keyboard layout generator 300 keyboard 310 finished acrylic material 320 alloy bond metal cover 330 microprocessor 340 lithium ion battery 350 micro-USB charging port 360 LED 410 silicone layer 420 touch sensor layer 430 acrylic layer 440 LED layer 450 acrylic blocks 500 layout of keys 510 character keys 520 space bar 530 cancel key 540 special character key 550 copy key 560 paste key 570 touch pad 580 sensitivity scroll bar 600 layout of keys 610 character keys 620 space bar 630 special keys 640 keys for language selection 650 key for adding a language 680 sensitivity scroll bar 700 layout of keys 710 directional keys 720 special key 730 special key 740 special key 750 special key 800 method 810 flowchart operation 820 flowchart operation 830 flowchart operation 900 method 910 flowchart operation 920 flowchart operation 930 flowchart operation 1000 keyboard driver 1100 mouse driver 1200 keyboard embodiment using micro-LED array projection 1210 silicone layer 1220 capacitive layer 1230 acrylic layer 1240 micro LED layer 1300 keyboard embodiment using projection bar 1310 acrylic keyboard 1340 projection bar 1400 keyboard embodiment using projection underneath keyboard 1410 acrylic layer 1420 support layer 1440 projection device 1500 keyboard embodiment using touchscreen 1510 touchscreen 1600 biometric analyzer 1610 biometric identifier 1620 biometric authenticator 1630 biometric behavioral analyzer 1640 biometric learning machine 1700 method 1710 flowchart operation 1720 flowchart operation 1730 flowchart operation 1740 flowchart operation 1750 flowchart operation 1760 flowchart operation 1770 flowchart operation 1780 flowchart operation 1790 flowchart operation 1800 obfuscator module

DETAILED DESCRIPTION

Embodiments of the present invention relate to a universal keyboard, referred to herein as the “ONE-KEYBOARD”, which is a universal solution to all key input to the computer, and is the first fully-compatible biometric keyboard.

The keyboard consists of a blank translucent surface, a capacitive array touch screen that transmits touch to the computer, and a projection system that projects the keyboard template or layout that is needed for each application. As described below, there are inter alia four types of projection systems: (1) micro-LED array applied to the under-surface of the keyboard, (2) projection system applied to a bar across the keyboard, (3) projection system that projects onto the surface from underneath the keyboard, and (4) touchscreen system.

The ONE KEYBOARD comes in a variety of sizes and in a software-only version. A user has a choice of silicone pads that adhere to the surface of the ONE KEYBOARD, in order to find the preferred “touch”. The ONE KEYBOARD is supported on two legs that are adjustable to the user's preferred angle. A small speaker in the keyboard allows the user to choose from a variety of pre-recorded sounds to simulate the “click” of a key and provide minimal haptic feedback. The user can choose a binary sound, which makes a sound at a single decibel level, or variable sounds that are louder or softer depending on the pressure applied to the key. The ONE KEYBOARD comes in wired or wireless (e.g., BLUETOOTH®) models. Both models display the internal circuitry through the acrylic, for aesthetic purposes. The touch sensors may be set to whatever threshold the user prefers, and the threshold may vary based on the application being used. There are optional accessories, including inter alia a mouse, microphone, webcam and speaker.

Reference is made to FIG. 1, which is a simplified diagram of a keyboard 100 for use in cooperation with a keystroke biometric analyzer, in accordance with an embodiment of the present invention. As shown in FIG. 1, keyboard 100 includes a blank translucent surface 110 for use as an input device. Translucent surface 110 may be inter alia a silicone surface. A capacitive layer 120 is mounted underneath translucent surface 110, for enabling detection of touch location and touch pressure on translucent surface 110. A projection system 140 projects a visual layout of keys of a keyboard on translucent surface 100. A controller 150 includes circuitry to control operation of the components of keyboard 100. Keyboard 100 includes a speaker 160, a microphone 165, a webcam 170, an accelerometer 175, and a USB connector 180. Accelerometer 175 measures small movements in the keyboard induced by a user's actions. Keyboard 100 also includes an optional wireless module 185, for short-range wireless communication such as BLUETOOTH®.

Keyboard 100 includes a biometric generator 190 operative to receive user input in conformance with the projected layout of keys, and to generate therefrom a time series of touch location and touch pressure data, for use as data by a keystroke biometric analyzer 1600. Biometric analyzer 1600 is described below with reference to FIG. 16. Keyboard 100 also includes an obfuscation module for protecting a user's privacy. Obfuscation module 1800 is described below with reference to FIG. 17.

Reference is made to FIG. 2, which is a simplified diagram of a keyboard 200 with interactive generation of layouts of keys, in accordance with an embodiment of the present invention. As shown in FIG. 2, keyboard 200 includes a blank translucent surface 210 for use as an input device. Translucent surface 210 may be inter alia a silicone surface. A capacitive layer 220 is mounted underneath translucent surface 210, for enabling detection of touch location on translucent surface 210. A projection system 240 dynamically projects a plurality of visual layouts of keys of a keypad on translucent surface 210, where each visual layout includes ASCII character keys or graphical buttons. A controller 250 includes circuitry to control operation of the components of keyboard 200. Keyboard 200 includes a speaker 260, a microphone 265, a webcam 270, an accelerometer 275, and a USB connector 280. Accelerometer 275 measures small movements in the keyboard induced by a user's actions. Keyboard 200 also includes an optional wireless module 285, for short-range wireless communication such as BLUETOOTH®.

Keyboard 200 includes a dynamic keyboard layout generator 290 operative to dynamically control projection system 240 to project different layouts of keys on translucent surface 210 in response to user activity on a computing device, to receive user input in conformance with a currently projected layout of keys, and to generate therefrom a time series of ASCII characters or button selections for input to the computing device.

It will be appreciated by those skilled in the art that the embodiments shown in FIGS. 1 and 2 may be combined into an embodiment that combines biometric generator 190 with dynamic keyboard layout generator 290.

Reference is made to FIG. 3, which is a simplified top view of a keyboard 300, in accordance with an embodiment of the present invention. As shown in FIG. 3, keyboard 300 is approximately 13″ in length and 5.5″ in width, and is formed by an acrylic or other translucent material 310 including inter alia glass, plexi-glass and a combination of such materials. The components of keyboard 300 are covered by an alloy bond metal cover 320 having a width of 0.75″, with upper corners curved in an arc of a circle of 0.5″ radius. Keyboard 300 includes a microprocessor 330 for registering and sending key information to a database, an 1100 mAh lithium ion battery 340, a micro-USB connector charging port 350, and an LED 360.

Although element 310 is indicated as being an acrylic material, this is not necessary for practice of the invention, and element 310 may alternatively be comprised of glass, plexi-glass or such other translucent material, or a combination of such materials.

Reference is made to FIG. 4, which is a simplified side view of keyboard 300 showing four layers, in accordance with an embodiment of the present invention. As shown in FIG. 4, keyboard 300 includes an upper layer 410 of silicone having a thickness of 0.05″, to provide user feedback. Beneath layer 410 is a layer 420 having a thickness of 0.15″ with a touch sensor. Beneath layer 420 is a layer 430 of acrylic having a thickness of 0.5″, to provide sturdiness. Beneath layer 430 is a layer 440 having a thickness of 0.05″, with a programmable high resolution LED screen. Underneath keyboard 300 are acrylic blocks 450, to angle the keyboard for ease of use.

Reference is made to FIG. 5, which is a simplified illustration of a layout of keys 500 for word processing, for use with keyboard 300, in accordance with an embodiment of the present invention. Layout 500 includes QWERTY character keys 510, a space bar 520, a cancel key 530, a special character key 540, and respective copy and paste keys 550 and 560. Layout 500 also includes a touch pad 570, and a scroll bar 580 for touch sensitivity.

Reference is made to FIG. 6, which is a simplified illustration of a layout of keys 600 for an alternate language, for use with keyboard 300, in accordance with an embodiment of the present invention. Layout 600 includes character keys 610 for a Korean alphabet, a space bar 620, special keys 630, and keys 640 for language selection. A key 650 is provided for adding additional languages. Layout 600 also includes a scroll bar 680 for touch sensitivity.

Reference is made to FIG. 7, which is a simplified illustration of a layout of keys 700 for an interactive MINECRAFT® game, manufactured by Mojang Synergies AB of Stockholm, Sweden, for use with keyboard 300, in accordance with an embodiment of the present invention. Layout 700 includes directional keys 710, and respective keys 720, 730, 740 and 750 for “FLY”, “TALK”, “INVENTORY” and “SPRINT”.

It will be appreciated by those skilled in the art that the layouts 500, 600 and 700 of respective FIGS. 5, 6 and 7, are interactively changed via projection system 240. In particular, both the appearance and the function of the keyboard layout changes dynamically, based on operations performed by a user.

Reference is made to FIG. 8, which is a simplified flowchart of a method 800 for using a keyboard to generate data for a keystroke biometric analyzer, in accordance with an embodiment of the present invention. At operation 810, projection system 140 (FIG. 1) projects a visual layout of keys onto translucent surface 110. At operation 820, capacitive layer 120 dynamically senses touch location and touch pressure on translucent surface 110 at a sequence of times. At operation 830, biometric generator 190 generates a data stream of touch location and touch pressure data for use by a keystroke biometric analyzer.

Reference is made to FIG. 9, which is a simplified diagram of a method 900 for interactively generating layouts of keys for a keyboard, in accordance with an embodiment of the present invention. At operation 910, dynamic keyboard layout generator 290 (FIG. 2) dynamically controls projection system 240 to project different ones of a plurality of visual layouts of keys of a keypad on translucent surface 210, in response to user activity on a computing device, where each visual layout comprises ASCII character keys or graphical buttons. At operation 920, capacitive layer 220 dynamically senses touch locations on the translucent surface at a sequence of times. At operation 930, dynamic keyboard generator 290 generates a data stream, such as a data stream of ASCII characters or button selections, at a sequence of times, for input to the computing device, based on the projected layout of keys and the sensed touch locations, at each time in the sequence.

It will be appreciated by those skilled in the art that the methods shown in FIGS. 8 and 9 may be combined into a method that combines biometric data generation with dynamic keyboard layout generation.

Reference is made to FIG. 10, which is a simplified diagram of a keyboard device driver 1000 for the ONE KEYBOARD, in accordance with an embodiment of the present invention. As shown in FIG. 10, functions of the keyboard driver include inter alia:

-   -   A. initializing the keyboard;     -   B. locking the computer, in response to any attempt to disable         the driver;     -   C. initializing a speaker and loading a sound file;     -   D. initializing a microphone;     -   E. initializing a BLUETOOTH® pairing;     -   F. initializing a webcam;     -   G. initializing a projection system;     -   H. projecting a display file onto the keyboard;     -   I. initializing a touch pad;     -   J. obtaining a time series of touch data from the touch pad; and     -   K. formatting the touch data for output as a continuous data         stream (X, Y, T_(D), T_(R), P, A), where         -   X is the horizontal location,         -   Y is the vertical location,         -   T_(D) is the time (in milliseconds) that the key is             depressed,         -   T_(R) is the time (in milliseconds) that the key is             released,         -   P is the pressure (in milligrams) placed upon the key, and         -   A is the acceleration vector (in m/s²) for small movements             in the keyboard induced by a user's actions;     -   L. map touch data to ASCII keystroke or bitmap data, as         appropriate;     -   M. format the keystroke or bitmap data for output; and     -   N. output via USB.

Data output from the keyboard via a device driver may use a file format and communications protocol that conform to an existing or future standard. The lowest level output from the ONE KEYBOARD is the continuous data stream of data (X, Y, T_(D), T_(R), P, A). In addition, the driver estimates the user's finger size, S, using an edge-detection algorithm, where S is the estimated two-dimensional area of the user's finger as estimated by detecting the diameter, d, of the finger while the key is depressed (e.g., S=¼πd²). The raw pixels covered by the finger are also made available.

When appropriate, touch data is converted (i.e., mapped) onto ASCII keystrokes, and, when needed, the data is converted to graphical data. For example, if the user presses the keyboard where the “J” key is located, the ASCII output for 3 is sent with the associated pressure measurement; if the user creates a signature on a touchpad, the signature is mapped to a bitmap file, with a corresponding “user pressure matrix”, which is a 3D matrix containing the 2D pressure applied along a time axis.

Keyboard device driver 1000 may be implemented in software, firmware, hardware, or a combination of software, firmware and hardware.

Reference is made to FIG. 11, which is a simplified diagram of a mouse device driver 1100, in accordance with an embodiment of the present invention. The mouse that accompanies the ONE KEYBOARD is essentially a miniature version of the keyboard, and is incorporated into the same application. Many optical mouse devices have been created with more than one button or wheel, such as the gaming mice (http://www.razerzone.com/gaming-mice) manufactured by Razer Pte Ltd of Singapore, and such as the MAGIC MOUSE® (http://www.apple.com/magicmouse/) manufactured by Apple Inc. of Cupertino, Calif., in order to facilitate the user's interaction with programs that require the same operations over and over again. This is popular in the gaming community. As another example, a radiologist uses the same features of “Zoom”, “Pan”, “Window” and “Level” to interpret 50 or 100 medical images a day. At this time, he can either use the same repetitive mouse clicks, or try to find a mouse with some added buttons; the mouse that accompanies the ONE KEYBOARD creates a custom panel of buttons. For anyone who does work that requires repetitive tasks, the mouse that accompanies the ONE KEYBOARD is a highly ergonomic solution. The mouse displays user-definable buttons, and collects a small subset of biometric data.

Mouse device driver 1100 may be implemented in software, firmware, hardware, or a combination of software, firmware and hardware.

The ONE KEYBOARD employs a projection system to dynamically adapt a layout of keys to the user's application. If the user is typing a document, the projected layout of keys conforms to a standard keyboard, and switches between languages, mathematical symbols and graphics, as needed. For a user who uses more than one language, the projected layout of keys includes keys in any language, and further includes a “Translate” button that enables the user to type in one language and have it translated to another language. There are hundreds of keyboard layouts being used throughout the world today, any of which may be projected on the ONE KEYBOARD, and the projected keys may be a single color, or may be color-coded, or may be any other design. When the user is working on a photo-book, for example, with a website such as SHUTTERFLY®, owned by Shutterfly, Inc. of Redwood City, Calif., the ONE KEYBOARD projects a section that shows inter alia a “Page Layout” button, a “Background” button, an “Add-a-Page” button, a “Theme” button, and a “Color” button. When the user adds photos to the book, the ONE KEYBOARD projects a section that shows inter alia an “Add Photos from Computer” button, an “Add Photos from Shutterfly” button, and an “Add Photos from Instagram” button. There are icons of photos, text and other objects that the user may drag into his book. The user may use gestures to edit a photo, resize the photo, change the contrast, brightness, hue, saturation, and make other adjustments. When the user switches between applications, such as working on a document, and then opening an Internet browser to look something up for the document, the keyboard switches between modes optimized for each application, and produces a set of custom buttons such as “Copy”, “Paste” and “Create Hyperlink”, to facilitate the interaction between applications. The keyboard works in a highly synchronized fashion with the user, creating the correct keys and icons for each application, and eliminating the need for hundreds of mouse clicks. If authentication is needed, the collected biometric data is used to verify the identity of the user using an external biometric analyzer.

As described below, there are inter alia four embodiments of projection systems: (1) micro-LED array applied to the under-surface of the keyboard, (2) projection system applied to a bar across the keyboard, (3) projection system that projects onto the surface from underneath the keyboard, and (4) touchscreen system.

Reference is made to FIG. 12, which is a simplified of a keyboard 1200 using a micro-LED array projection system, similar to keyboard 300 shown in FIG. 4, in accordance with a first embodiment of the present invention. Shown in FIG. 12 is a silicone surface 1210, exposed for touch by a user. Underneath silicone surface 1210 is a capacitive touch layer 1220, for detecting touch location and touch pressure when a user touches silicone surface 1210. Underneath capacitive touch layer 1220 is an acrylic layer 1230.

A pattern of keys is projected onto silicone surface 1210 by a micro LED array 1240, underneath acrylic layer 1230.

A controller (not shown) receives user input in conformance with the projected layout of keys, and generates a time series of touch location and touch pressure data therefrom. The touch location and pressure data may be used inter alia by a keystroke biometric analyzer, as explained below.

Reference is made to FIG. 13, which is a simplified diagram of a keyboard 1300 using a projection system applied to a bar across the keyboard, in accordance with an embodiment of the present invention. Shown in FIG. 13 is an acrylic keyboard 1310 with a projection bar 1340.

Reference is made to FIG. 14, which is a simplified diagram of a keyboard 1400 using a projection system that projects onto the surface from underneath the keyboard, in accordance with an embodiment of the present invention. Shown in FIG. 14 is an acrylic surface 1410. A support layer 1420 is underneath acrylic surface 1410. Within support layer 1420 is a projector device 1440, which projects a pattern of keys onto acrylic surface 1410.

Reference is made to FIG. 15, which is a simplified diagram of a keyboard 1500 using a touchscreen, in accordance with an embodiment of the present invention. Keyboard 1500 uses a touch pad 1510.

Two or more of the projection systems of FIGS. 12-15 may be combined together into a multi-projection keyboard.

One of the central features of the ONE KEYBOARD is that it uses behavioral biometrics to learn the touch patterns of every individual, via a process termed “keystroke dynamics”. This is a security feature to supplement conventional means of authentication, such as username and password, and may also be used as a form of error correction. At the basic level, the device registers the behavioral data associated with each time the user touches the keyboard. Over a short period of time, the data gathered creates a “behavioral profile” for the user. The behavioral profile is the set of numeric and categorical features that describe the keyboard usage history, including key press and release timings, pressure, acoustics, keyboard motion, and the shape of the finger mapped onto a two-dimensional space. From the behavioral profile, biometric information can be extracted to create a “biometric template”. The biometric template is a reduced set of features that are highly reproducible and specific for each individual. E.g., the pressure and finger shape may be used to uniquely identify a particular user with high probability. Some of the variations in pressure and finger shape between different users can be attributed to (a) physical traits of the user, such as finger size and strength, (b) the distance from the center of the keyboard, and (c) the user's typing proficiency. Once created, the template is a valuable part of the system. The biometric template may be used to grant and restrict access to a system, identify the keyboard owner, and generate a unique encryption key that can be used to digitally sign documents.

Reference is made to FIG. 16, which is a simplified diagram of biometric analyzer 1600, in accordance with an embodiment of the present invention. As shown in FIG. 16, biometric analyzer 1600 includes four primary components; a biometric identifier 1610, a biometric authenticator 1620, a biometric behavioral analyzer 1630, and a biometric learning machine 1640.

Biometric identifier 1610 generates and stores the user's biometric template, which represents the unique and identifiable behavior attributes of the user. As the user's behavior changes over time, such as due to increased typing proficiency, typing impairments, and changes in physiology, the biometric template is updated. This is necessary so as to mitigate the “template aging effect”, a phenomenon encountered in biometrics in which the user's biometric template becomes less effective over time. Biometric learning machine 1640 implements an online learning mechanism to adapt to these changes in the user's behavior and to respond robustly to changes in the environment, such as keyboard positioning and ambient noises or vibrations.

Biometric authenticator 1620 operates in two modes: static and continuous. In static mode, an authentication or identification decision is made at discrete points in time using all available information up to that point, such as at the beginning of a session or logging into a website. In continuous mode, an authentication or identification decision is made continuously as the user interacts with the keyboard; for authentication decisions in this mode, the biometric authenticator chooses to either allow the session to continue, deeming the user as genuine, or blocks the user from the session, deeming the user as an impostor. For identification decisions in this mode, the keyboard continuously recognizes the identity of the active user, such as in a shared multi-user environment.

“Affective computing” is a field of study that aims to build systems capable of detecting and responding to the user's affect, or emotional state. In a desktop or laptop environment, the ability to detect the user's affective state can enable a more integrated and productive environment. Biometric behavioral analyzer 1630 recognizes the affective state of the user from the recorded behavior profile in order to provide a more robust and dependable computing environment. Affective states and possible responses include inter alia:

Affective State Response stress dynamically adjusting the keyboard interface to decrease user workload and increase productivity frustration dynamically optimizing the keyboard interface to reduce errors; and confusion dynamically adjusting the keyboard interface to provide assistance and additional relevant information

With the user's behavioral profile, the ONE KEYBOARD improves workflow. Based on patterns gleaned from the user's experience, the ONE KEYBOARD corrects common mistakes made repeatedly by the user, and suggests moving the position or layout of various aspects of the keyboard for improved comfort. By determining the size of a user's fingers, and the type and number of errors made by the user, the ONE KEYBOARD suggests changes in the layout of keys that can improve the user's experience. E.g., a larger set of keys may be more efficient for certain users. On a wider scale, a company may utilize aggregated behavioral profile data to identify patterns among large numbers of employees that might be slowing productivity. A cloud-based system, when applied to the user profile data, determines ways to improve workflow in a widely used program, for example, such as PHOTOSHOP®, developed and marketed by Adobe Systems of San Jose, Calif. Software developers may desire the ability to study aggregated behavioral data in order to improve the development of their next generation of applications.

Security is another major component of the ONE KEYBOARD. With the user's biometric template, the ONE KEYBOARD quickly detects when someone other than an authorized user is trying to access the system. Within a few lines of typing, the biometric template of the typist discriminates between an authorized user and an intruder. Companies interested in network security use this as a means of ensuring that only the correct user accesses each device. Common examples of this are on-line courses and test-taking, on-line e-commerce, and social networking companies who wish to prevent on-line bullying by “anonymous” users. Once the ONE KEYBOARD is attached to a computer, the driver can prevent anyone from detaching it and attempting to access the computer with a non-biometric keyboard. Currently, many behavioral biometric programs not only reject intruders, but they actually identify the intruder by their own behavioral biometric template.

Protecting the user's privacy is another major feature of the ONE KEYBOARD. Keystroke dynamics is a technique that can be used to legitimately identify and authenticate a user by a trusted application, such as when logging into a secure banking website or during an online course. However, there are numerous scenarios in which a user's keystroke dynamics are exposed to an untrusted application. This dilemma is often encountered in web applications, whereby a single webpage may load dozens of third party modules that provide functionality through an external application programming interface (API). Given the lack of special permissions required to capture keyboard events in modern web browsers, an untrusted web application or third-party module can passively record the user's key press and release timings and use this information to track the user's identity. This presents a privacy concern since a malicious application can perform user identification and verification remotely via keystroke dynamics without the user's cooperation or knowledge. Since this type of attack relies only on the user's typing behavior, the user's identity may be compromised even when accessing the web application through an anonymizing network, such as The Onion Router (TOR). From this perspective, keystroke dynamics represents a form of “behavioral tracking”, the process by which an advertiser or other third party is able to track user identity and demographics based on his online activity.

Obfuscation module 1800 of The ONE KEYBOARD mitigates this threat by masking the user's keystroke dynamics from any application which receives keyboard input. Obfuscation module 1800 introduces a small random delay to each key press, key release, and touch event by temporarily buffering the event on the device before releasing it to the host computer. The buffer duration is chosen in such a way so as to meet two criteria: 1) the user's keystroke dynamics appear obfuscated to any application that receives keyboard input, mitigating the possibility of an untrusted application from performing user identification or verification; and 2) so as to maximize the responsiveness of the keyboard, introducing a delay that is unnoticeable to the user. The ONE KEYBOARD is the first keyboard designed to protect the user's privacy in real time with a random delay that adapts to the user's typing speed.

There are numerous legitimate uses of keystroke dynamics employed by trusted applications and the ONE KEYBOARD may preserve the intended functionality of these applications. Such behavioral biometric services are provided by companies including TypingDNA, Behaviosec, KeyTrac. The ONE KEYBOARD is compatible with all of these applications, granted they are trusted by the user. This functionality is provided through an application-specific permissions mechanism, whereby the user may choose to trust certain applications, granting them access to the user's un-obfuscated keystroke timings, while allowing other untrusted applications access only to the obfuscated keystroke timings.

Using the ONE KEYBOARD and its associated methodology, on-line learning sites such as Coursera of Mountain View, Calif., and Khan Academy of New York, N.Y., testing companies such as The College Board of New York, N.Y., and ACT of Iowa City, Iowa, and any company seeking to verify/authenticate users who are accessing their systems via a remote connection, will increase the security of their systems dramatically.

Reference is made to FIG. 17, which is a simplified flowchart of biometric analysis and authentication, in accordance with an embodiment of the present invention. At operation 1710, biometric identifier 1610 generates a behavioral profile and a biometric template of the user. At operation 1720 the user attempts to access a system using keyboard 100. At operation 1730 biometric authenticator 1620 identifies the user based on his biometric template. At operation 1740 biometric authenticator 1620 grants or restricts the user's access to the system, based on the user's biometric template.

At operation 1750 obfuscation module 1800 obfuscates the user's key press and release timings, to prevent suspicious application from recording the user's key press and release timings and tracking the user's identity. Obfuscation of key press and release timings may be performed inter alia by temporarily buffering the key press and release events, thereby introducing buffer duration errors into the timings.

At operation 1760 biometric authenticator 1620 grants trusted applications access to the user's un-obfuscated key press and release timings. At operation 1770 biometric authenticator 1620 makes continuous decisions as to the identity and authenticity of the user, based on his biometric template. At operation 1780 biometric behavioral analyzer 1630 responds to the user's affective state by instructing projection system 140 to update the layout of keyboard 100. At operation 1790 behavioral learning machine 1640 adaptively updates the user's biometric template to compensate for template aging and changes in the environment.

An important component of the ONE KEYBOARD is software device driver 1000 for the keyboard, shown in FIG. 10, which contains the necessary calibration and settings for the keyboard to be customized for each user.

Biometric learning machine 1640 uses a biometric learning algorithm. This algorithm collects data from the keyboard and then utilizes that data to “learn” from each user's experiences. Typing mistakes tend to be repetitive, such as touching a certain key too lightly, or misspelling some specific words because of inverting the letters. If a user misspells a word repeatedly, the algorithm determines if the error is due to incomplete activation of a key, or due to another error such as inversion of letters. It then maintains a file of these learned experiences for each user and compensates for them, so that the user experiences an error-free interaction. Preferably, the learning algorithm is separate from the ONE KEYBOARD. At present, there are numerous commercial entities utilizing biometric data. The ONE KEYBOARD is compatible with all of these applications.

Over time, biometric learning machine 1640 determines which applications a user uses most of the time. The universal keyboard suggests optimal keyboard layouts, based on the applications used most of the time, which enable a user to decrease his number of keystrokes, and improve his efficiency and experience.

The ONE KEYBOARD comes with a device driver. In addition, there is a small program that allows the user to choose from standard keyboard layouts, or design his own custom layout, using a simple graphical interface. There is an error-correcting program that corrects typing errors, similar to SWIFTKEY®, developed and manufactured by TouchType Limited of London, UK. There is an optional cloud based service that includes better “learning” from the user's experiences, and security systems that ensure that each user matches their biometric security profile.

The ONE KEYBOARD is the most innovative change to human-computer interaction (HCI, http://en.wikipedia.org/wiki/Human%E2%80%93computer_interaction) with desktop and laptop computers in the past decade, and is the last keyboard anyone will ever need to buy.

One having the benefit of the subject disclosure will appreciate that there are many variations of the keyboard of the subject invention. The present invention may be embodied in applications for cellular phones, including inter alia the IPHONE® and IPAD® manufactured by Apple Corporation of Cupertino, Calif., and the ANDROID™ phones manufactured by Samsung Electronics Co., Ltd of Korea, using built-in technology of the phones to collect biometric data.

Furthermore, add-on components to the ONE KEYBOARD device driver make use of the behavioral data collected during operation. These components inter alia detect fatigue and stress, detect mental states and/or moods, and diagnose physical ailments such as arthritis and Parkinson's disease. As such, the ONE KEYBOARD may be used by qualified medical professionals. Alternatively, or additionally, such information may be used to determine when a person may be more likely persuaded by a particular type of advertisement.

In the foregoing specification, the invention has been described with reference to specific exemplary embodiments thereof. It will, however, be evident that various modifications and changes may be made to the specific exemplary embodiments without departing from the broader spirit and scope of the invention as set forth in the appended claims. Accordingly, the specification and drawings are to be regarded in an illustrative rather than a restrictive sense. 

What is claimed is:
 1. A biometric analyzer, comprising: a biometric generator, receiving user input in conformance with a layout of keys, and generating therefrom time series, over a period of time, of touch location data, of touch timing data and of touch pressure data, for transmission as a data stream to a biometric identifier, wherein the time series of touch location data comprises a series of locations of keys that are pressed by the user, wherein the time series of touch timing data comprises a series of times at which keys are depressed and times at which the depressed keys are released, and wherein the time series of touch pressure data comprises a series of pressure magnitudes; and a biometric identifier, receiving the time series of touch location, touch timing and touch pressure data from said biometric generator, deriving a biometric template of the user therefrom, and subsequently when the user tries to access a system using a keyboard, identifying the user based on his biometric template, and granting or restricting the user's access to the system, based on his biometric template.
 2. The biometric analyzer of claim 1, wherein said biometric generator further generates a time series of acoustic data comprising a raw acoustic waveform recorded during keyboard operation, and wherein said biometric identifier derives the biometric template of the user also from the time series of acoustic data.
 3. The biometric analyzer of claim 1, wherein said biometric generator further generates a time series of motion data comprising a raw accelerometer and gyroscopic waveform recorded during keyboard operation, and wherein said biometric identifier derives the biometric template of the user also from the time series of motion data.
 4. The biometric analyzer of claim 1, further comprising a continuous biometric authenticator, receiving in real-time the time series of touch location, touch timing and touch pressure data generated by said biometric generator, and making continuous decisions as to the identity and authenticity of the user based on the user's biometric template.
 5. The biometric analyzer of claim 4, further comprising: a projection system dynamically projecting a visual layout of keys; and a biometric behavioral analyzer, coupled with said continuous biometric authenticator, recognizing intentions and affective states of the identified user based on the time series of touch location, touch timing and touch pressure data, and responding to user's affective states by instructing said projection system to update the layout of the keyboard.
 6. The biometric analyzer of claim 4, further comprising a biometric learning machine, adaptively updating the user's biometric template over time to compensate for the effects of template aging and changes in the user's surrounding environment.
 7. The biometric analyzer of claim 1, further comprising an obfuscator module obfuscating the user's keystroke timings and thereby preventing a suspicious application from performing user identification and verification based on the user's keystroke dynamics.
 8. The biometric analyzer of claim 7, wherein said obfuscator module grants a trusted application permission to capture the user's keystroke dynamics by granting the trusted application access to the un-obfuscated keystroke timings.
 9. The biometric analyzer of claim 7, wherein said obfuscator module introduces a random time delay to each key press and release event by temporarily buffering the event.
 10. A method for biometric analysis, comprising: receiving user input in conformance with a layout of keys; generating, from the user input, time series, over a period of time, of touch location data, touch timing data and touch pressure data, wherein the time series of touch location data comprises a series of locations of keys that are touched by the user, wherein the time series of touch timing data comprises a series of times at which keys are depressed and times at which the depressed keys are released, and wherein the time series of touch pressure data comprises a series of pressure magnitudes; deriving a biometric template of the user from the times series of touch location, touch timing and touch pressure data; and subsequently, when the user tries to access a system: identifying the user based on his biometric template; and granting or restricting the user's access to the system, based on the user's biometric template.
 11. The method of claim 10, wherein said generating further generates a time series of acoustic data comprising a raw acoustic waveform recorded during keyboard operation, and wherein said deriving derives the biometric template of the user also from the time series of acoustic data.
 12. The method of claim 10, wherein said generating further generates a time series of motion data comprising a raw accelerometer and gyroscopic waveform recorded during keyboard operation, and wherein said deriving derives the biometric template of the user also from the time series of motion data.
 13. The method of claim 10, further comprising: receiving the time series of touch location, touch timing and touch pressure data in real-time; and making continuous decisions as to the identity and authenticity of the user based on the user's biometric template.
 14. The method of claim 13 further comprising: recognizing intentions and affected states of the identified user based on the time series of touch location, touch timing and touch pressure data; and responding to the user's affective states by updating the layout of the keyboard.
 15. The method of claim 13 further comprising adaptively updating the user's biometric template over time to compensate for the effects of template aging and changes in the user's surrounding environment.
 16. The method of claim 10, further comprising: obfuscating the user's keystroke timings and thereby preventing a suspicious application from performing user identification and verification based on the user's keystroke dynamics; and granting a trusted application permission to capture the user's keystroke dynamics comprising granting the trusted application access to the un-obfuscated keystroke timings.
 17. The method of claim 16 wherein said obfuscating comprises introducing a random time delay to each key press and release event by temporarily buffering the event.
 18. The method of claim 17 wherein the buffer durations are chosen so as (i) to obfuscate the user's keystroke dynamics and thereby prevent an application from performing user identification and verification based on the user's keystroke dynamics, and (ii) to maximize responsiveness of the application. 